Gas tube and resistor shunt to prevent distortion at impulse contacts



Aug. l, 1950 J. R. DEWAR GAS TUBE AND REsIsToR sHUNT To PREVENT DIsToRTToN AT IMPULSE coNTAcTs 2 Sheets-Sheet 1 Filed April 25, 1947 5x2-LECTOR RSZ INVENTOR. 1//7/755 f?. 05W/7l? BY A0 W HTT/Vfy Aug. 1, 1950 J. R. DEWAR 2,517,291

GAS TUBE AND RESISTOR SHUNT TO PREVENT DlsToRTIoN AT IMPuLsE CONTACTS Filed April 25, 1947 2 SheetS-Sheet 2 /r/.s 107 D BYQv HTTOR/VEY Patentecl Aug. l, 1950 UNITED STATES PATENT OFFICE GAS TUBE AND RESISTOR SHUNT TO PREVENT DISTORTION AT IMPULSE CONTACTS 6 Claims.

This invention relates to an electrical impulsing arrangement which has particular utility in an impulse or stepping circuit for use in controlling the operation oi selective switching means in an automatic telephone system or the like.

In many impulse-controlled electrical devices, it is highly essential to the reliable operation thereof, that the ratio of breaks to the "makes in the electrical current, constituting the impulses, be maintained uniform even under the varying conditions encountered in service. Specilically in an automatic telephone system, switching means is controlled by impulses in an impulsing or stepping circuit, the impulse ratio of which, namely, the lengths of the breaks in relation to the makesf is for example as sixty is to forty. Any material distortion or change in the impulse ratio from that chosen, will result in the erratic operation of the switching means with the consequent wrong substation selection or so-called wrong numbers.

Much of the pulse-ratio distortion encountered in former automatic telephone systems has arisen because of the spark arresting means used to protect the interrupting contacts in the stepping circuit. The conventional spark arresting means for the contacts of a relay or magnet to be'protected, comprises a resistor or a capacitor and a resistor connected across the same, the

capacitance and resistance of which tend to distort the impulse ratio. The seriousness of this distortion has caused telephone engineers notably those of the British Post Office system and the American Telephone and Telegraph Company to develop various arrangements for correcting or restoring the original pulse form after the distortion has occurred. An example of one of these pulse correcting systems is disclosed in the patent to Newby 1,829,837, granted November 3, 1931, to the American Telephone and Telegraph Company as assignee.

In accordance with the present invention there is provided an arrangement which substantially prevents impulse ratio distortion and thereby obviates the need for impulse correcting equipment. The present arrangement also provides arc-suppression at the rhythmically operated contacts in an impulsing system, whereby the need for precious metal contacts can be eliminated in many f instances.

The various features and advantages of the present invention will appear from the detailed description and claims when taken with the drawings in which:

Fig. l is a diagrammatic showing of the invention applied to a selector switch circuit disclosed as a part of a telephone connection, the other switches necessary in completing the connection having been omitted;

Fig. 2 is a diagrammatic showing of the invention applied to a P. B. X trunk repeater circuit;

Fig. 3 is a front view of the glow discharge lamp and resistor enclosed in cylindrical insulatting tube having a window therein While Fig, 4 is a longitudinal section through the lamp and the related parts;

Fig. 5 illustrates the invention incorporated in a connector circuit; and

Fig. 6 is a diagrammatic showing of the invention in combination with a counting relay chain and impulse directed means for operating said chain.

Selector switch It is believed that the invention will best be understood by first describing the operation of the circuits of a Strowger type selector switch, shown in Fig. 1, in extending a call. When the subscriber at the substation A removes his receiver from his desk stand, his telephone line including the tip conductor 5 and the ring conductor 6 are extended in series to an idle selector switch which is assumed to be the selector switch illustrated. The calling subscribers line may be eX- tended to this idle selector switch either by a line switch (not shown) individual to the calling line or by a line finder (not shown) which hunts for and extends calling lines to an idle trunk and selector switch in the well-known manner,

On the seizure of the mentioned selector switch, a circuit is completed from the impulse or stepping relay 'l from grounded battery, upper winding of this relay, back contact and upper armature of the back bridge relay 8, ring conductor E and tip through the calling substation A, tip conductor 5, armature and back contact of relay 8, lower winding of the relay 'l to ground. The irnpulse relay l, when thus energized, closes an operating circuit for the slow releasing relay l0, from grounded battery, winding of this relay, front contact and armature of the impulse relay l, back contact and armature of the relay 8 to ground. The relay Ill controls the release or" the selector in the well-known manner as will be fur' ther referred to. If the selector herein illustrated is used as a rst selector, the subscriber on dialing the rst digit of the wanted subscribers number, will cause the impulse relay 1 to retract and attract its armature once for each impulse corre- 3 sponding to the digit dialed. When the impulse relay 1 retracts its armature it closes an operating circuit for the primary or vertical motor magnet I I. Since the switch herein referred to moves vertically in response to impulses, it moves its brushes vertically for each pulse to select a group of trunks. The circuit for the motor magnet II is completed rom grounded battery winding of this magnet I I, winding of the slow releasing change-over relay I2, front contact and lower armature of slow releasing relay Ill, back Contact and armature of the impulse relay l, back contact and lowermost armature of the relay 8 to ground. As a result of the operation of the motor magnet II the ring brush i3, the tip brush i4 and the test brush I5, are positioned opposite the rst group of trunks appearing in this switch, On the completion of this rst stepping movement of the selector switch, the off normal switch contacts ON are closed. As soon as the off normal switch ON is thus operated, an energizing circuit is completed for the test relay Il. The circuit for this relay is extended from grounded battery, winding of relay Il, o normal contacts I8, conductor 20, armature and front contact of the slow releasing change-over relay I2, armature and front contact of the slow releasing relay I!) to ground. The relay Il at its inner armature and front contact` closes a break point inthe operating circuit of the secondary motor magnet I 6. However, the circuit for this magnet is held open at the back contact and continuity spring of the change-over relay I2 until the close of the series of dialing impulses being transmitted to this switch. At the close or"Y this series of impulses, change-over relay I2v releases and Athesecondary motor magnet IS then eiects a trunk hunting movement in the secondary or rotary direction to advance the brushes I3, I i and i5 into the selector bank where they contact the terminals of the rst trunk in the selected group. The operating circuit for the motor magnet i5 is completed from grounded battery, winding of this magnet, inner front contact and armature of the relay Il, back contact and continuity spring of the change-over relay I2, upper armature and front contact of the slow releasing relay It lto ground. It will be noted that on 'the release of the change-over relay I2, the original energizing circuit or the relay Il, which included conductor IS, is interrupted at the upper armature and front contact of the slow releasing relay i2. However, an alternative circuit is closed lfor the relay Il from grounded battery, its winding, oir normal contacts I8, conductor 20, armature and back contact of the secondary motor magnet I5, conductor 2|, back contact and continuity spring of the change-over relay I2 (-now deenergized) upper armature and front contact of the slow releasing relay I to ground. The'secondary motor magnet I5 is operated in this circuit to advance the brushes I3, I4 and I5 of the selector switch into engagement with the set 'of contacts individual to the rst trunk in the selected group. When the secondary motor magnet I5 operatesv in the circuit just described, it opens its armature and back contactand thereby interrupts' the energizingcircuit ofthe relay Il which had been completed therethrough. If it is assumed that the rst trunk in the selected group is busy, this vcondition will be indicated by the presence of ground on the test terminal with which the test brush `I5 is now in engagement. As a result of this condition, the relay Il will again beenergized. However, in this instance it will be energized in a circuit from grounded battery, winding of relay Il, off normal contact I8, conductor 2li, armature and back contact of the magnet It, conductor 22, back contact and uppermost armature of the relay 8, conductor 23 to the test brushes I5 and thence to ground over the test terminal of the busy trunk. When the relay Il is thus energized, it completes again the operating circuit for the secondary motor magnet IS previously described. The magnet I6 is thus operated and advances the switch brushes I3, I4 and I5 an additional step into engagement with the set oi terminals of the next trunk in the group. Also, when the motor magnet i6 operates, it opens its armature and back contact and thereby interrupts the operating circuit of the relay il'. This alternate operation of the motor magnet Iii and the relay Il due to the interruption or" the operating circuit of the relay Il by the motor magnet I6 and the subsequent interruption of the circuit of the motor magnet Iii by the relay Il, continues until the test brush It of the selector switch encounters the test terminal of an idle trunk in the selected group which termi-- nal is 'characterized by the absence of ground potential thereon.

It will be noted that the backbridge relay 8 is held inoperative during the period that the selector switch is hunting for an idle trunk. This is due to the fact that the relay 8 is short-circuited from ground at each busy trunk, test brush I5, conductor 213, upper armature and back con tact of relay 8 to the upper terminal of this relay. Also, ground potential is applied through the upper front contact and armature of relay Ill, conductor 25k to the lower terminal of the winding of relay 8. When, however, an idle trunk is located, the mentioned short-circuit about the winding of relay 8 no longer prevails but is now operated in a circuit completed from grounded battery, winding ofr relay il, contacts I8, conductory l2li, armature and back contact of magnet I 6, conductor 22, winding of relay Si, conductor 25, armature and front contact of relay I0, to ground. While relay 8 operates in this circuit, relay Il, which is marginal, does not operate. When re'- lay 8 operates, it extends the tip and ring sides of the subscribers line through the tip and ring brushes of the selector switch to the succeeding switch, such as a `selector or connector (not shown) to beV used in extending the connection. When. the relay 8' operates, it cuts oil the impulse relay I -from control over the subscribers line. Relay l, then, deenergizes and thereafter the slow releasing relay Id deenergiaes. Before the slow releasing relay` lil. deenergizes, to remove ground potential from conductor l5-in the operating circuit of relay 8, a substitute circuit for relay 8 is completed from the lower terminal 8 ofthe winding of relay upper iront Contact and armature of this relay, conductor 23, test brush I5 and thence to `ground at a relay similar to relay vI il, of the seized succeeding switch. The release magnet 2tr does not operate at this time because its operating circuit is interrupted' at the back contact and lowermost armature of the back bridge relay 8. However, at the time of releasing the connection, the back bridge relay 8 will be de'- energized in the well-known manner. At this time the releasemagnet 2t is operated to release the switch i-n a circuit extending from grounded battery, winding of magnet 26, oi normal con-v tacts 21, back contacts andarmatures of relays lil, l and 8 to ground. A l

From -the foregoing description itl will be un# derstood that when the impulse or stepping 'relay 1 responds to the dial impulses, the current in .the ystepping relay is interrupted, in synchronism with each impulse of the dial at the calling substation. The impulsing contacts of the stepping relay are closed each time that the stepping relay restores, and at that time the motor magnet Il (or counting relays to be referred to hereinafter in the modification of Fig. 6) are actuated. The impulsing contacts are opened when the stepping relay is reoperated. At this time the impulsing contacts must open the circuit to the motor magnet or counting relays of the automatic system. The motor magnet or counting relays, because they must respond to rapid interruptions, areof relatively high impedance, and when the circuit to them is opened, a voltage much higher than the operating voltage, for eX- 'ample nity volts used in the telephone system, is impressed across the impulsing contacts. If these contacts were not protected, the breaking of the current and the resultant rise in voltage across the contacts, would cause an arc discharge across the Contact gap, which would change the pulse ratio and eventually destroy the contacts.

The conventional arrangement for protecting these contacts is to provide a condenser in series -with a resistor across the contacts. This arrangement in some cases reduces the arc discharge but eventually the contacts are destroyed. However, such an arrangement introduces electrostatic capacity into the circuit to the motor magnet or counting relays, which tends to slow the release of the magnet or relays because of the charged condition of the condenser. This slow releasing effect can be explained in the following manner. When a resistor and condenser are used to shunt arcontact for arc suppression, the shunt causes a'drop in potential across the contacts, when the contacts open. The condenser charges relatively slowly and permits some ionization across the contact gap. When the contact gap widens vthe arc is cut ofi and the condenser becomes charged.

This charged condenser at this time is in series with the operated motor magnet or counting relay, and tends to hold it operated. In fact, many circuits employ a condenser across a relay winding to slow the release of the relay. Incidentally, the patent to Matousek No. 2,322,650, granted June 22, 1943 (Cl. P19- 18), discloses the use of an electron tube preferably of the gas-nlled discharge type for slowing the release of a relay or as stated in that patent, the release period of the relay is enhanced by utilizing an electron discharge tube to sustain the current flow through the winding of the relay It should aso be noted that the speed of the dials are not uniform, and as the values of the condenser and resistor are fixed, complete arc suppression can-` not be obtained. The charge and discharge rate of the condenser also varies with the speeds of various dials and the action of the rnotor magnet or counting relays cannot be in synchronism with the pulse ratio of the dial. In accordance with the present invention, an arc discharge device L in series with a suitable resistor R are connected across the normally closed impulse contacts of the impulse relay to prevent impulse ratio distortion, thereby effecting impulse stabilization, and also to prevent arcing at these contacts. Preferably the device L and the resistor R are contained in a windowed tube T of insulating material which is sealed at its ends. The overall dimensions of the tube can lbe one and one-quarter ncheslong andthreeeighths of an inch in diameter. While several diierent types of arc discharge devices may be used, it is preferable to use a neon glow lamp of the type now sold by the. General Electric Cornpany under the code number NEZ. As shown in Figs. 3 and 4, this glow lamp comprises two spaced electrodes in a neonl atmosphere or the like enclosed in a sealed glass envelope. This glow lamp is so designed that the gas therein will break down or ionize on the application of ninety volts thereto but maintains its ionization at a sustaining voltage of only eighty volts. Both of these voltagesare considerably higher than the voltage of the operating battery of the system which is assumed to be fifty volts. Therefore, the presence of the neon glow lamp and resistor across the contacts of the impulse relay 'I will not affect the operation or rele-ase of the motor magnet (or counting relays Fig. 6)

It should be pointed out that the glow lamp does not retain an electrostatic charge. This arises from the fact that the electrodes are suitably spaced in the neon atmosphere through which a charge which might tend to accumulate, leaks away since some emission is always present in the lamp.

Furthermore, the neon lamp and resistor pass Very little current (approximately .003 ampere in the case assumed) and that current passes only for an instant. These elements pass current in an electrical circuit as the equivalent of a counter electromotive force with an internal resistance. All gaseous-conduction lamps, of which the neon glow lamp is one, have a negative or run-away characteristic. If the lamp were connected directly across a source of Voltage sufciently'high to ionize the gas, the current would immediately rise to such values as to destroy the lamp. In accordance with the present invention the glow lamp has connected in series therewith the resistor R which in the example here assumed has a value of four thousand ohms so that the run away action will be prevented and the tube will not be destroyed.

Trunk repeater circuit In Fig. 2, the invention is shown applied to a l?. B. X trunk circuit of the repeating coil type which is provided with through supervision and with operator or subscriber dialing. Let it be assumed that an incoming call has been extended vto the conductors 50 and 5| of the trunk circuit herein illustrated. In the course of extending the call to this trunk, ringing current from the distant central office operates relay 52 which locks up mechanically in the well-known manner and lights the incoming lamp 53. When the operator in response to the lighting of the lamp 53 answers the call by operating the listening key LIST, the slow releasing relay 55 is operated from ground at the contacts 56 of the ringing key RING. conductor 58, inner armature and back contact of the slow releasing relay 53, conductor Si), contacts 6| of the listening key, now closed, conductor 62, winding of the slow releasing relay 55 to grounded battery. The relay 55 locks up through its armature 63 and iront contact, armature and back contact of relay 59, conductor` 58, contacts 56 of the ringing key to ground. The operation of the relay 55 unlatches the armature spring oi the relay 52 thereby permitting relay 52 to re# lease and thereby extinguishing the incoming signal 53. By the operation of rel-ay 55, the repeating coil is also closed across the incoming line to trip the machine ringing and to give supervision to the distant centra-1 office. The green 7 hold" lamp G4 is lighted through a contact "i3 of relay 5-5`to ground on the ringing key, This indicates to the P. B. X operator that the call has been Iautomatically held.

Ifthe'inccming call is to be extended to a subscribers telephone line, the pl-ug in which, this trunk terminates is inserted in the line jack of this line and the ringing .key RK is depressed. Ground from the 4sleeve of the call subscribers line, holds the relay 55 operated while 'the ringing :key RING is depressed. The mentioned ground is applied over the conductor El, armature and back contact of relay 6B, .conductor 6.9, armature and back contact of relay E59, armature and front contact of relay-55, Winding of this relay to ground.

When the subscriber at the called substation answers the'relay vE8 is operated from grounded battery, winding of this relay through the repeating coil l l, conductor l2, contactsl of ringing key, co-ntacts 'lli of the night Vkey NK, conductor'l, through the ring conductor of the subscribers line, thence through the tip side of this line, tip conductor i6 of the trunk, contacts ll of the night key, contactsl of the ringing :ey now closed, conductor T9, winding 8G or" the repeating coil to ground. The operation of the relay 68 closes a circuit from ground on the sleeve of the called subscribers line, to operate the relay 59. The circuit for the relay 5S is traceable Afrom grounded battery, winding of this relay, front contact vand armature B1 of relay 58, conductor 6l, to the ground on the mentioned sleeve of the subscribers line. The relay 59 when operated connects the repeating coil across the 'trunk leading to the central ofce. When relay 59 operates, it eiects the release or" the relay 55 so that the green hold lamp t is extinguished.

Transmitter battery to the called telephone station is supplied locally from the Arelay 68 and ythe repeating coil. Supervision to the P. B. X operator and tothe central office operator is under the control of the called subscribers substation telephone. Disconnect supervision is provided for l.the P. B. X and central office operators when the subscriber at the called substation hangs up.

Out-going calls Ato "manual oce If the P. B. X operator `vvishes to 'make a central 'o'iice call, the listening key LIST is operated as before. key effects the operation of the relay '55 as previously described. The relay 55 is then Vlocked operated through its lower armature and contact B3, and through the break contact and armature of relay 59, conductor 58, to ground .on the ringing key as already set forth. The repeating coil is also closed across the connection to give super- Vision to the distance central ofce. The green hold lamp ,64 is lighter through a contact of the relay 55 to ,ground on the ringing key .as already setforth. This indicates to the vP B. .X operator that the call has been .automatically held as already set lforth. The repeating coil which at this time is bridged across the trunk operates av relay (not shown) in the ,central cnice to light a lamp there. Battery is supplied to the P. B. X operators transmitter locallyfrom the retard coil in the operators telephone circuit (not shown).

When the P. .B. X operator Wishes `to recall the central oice operato-r, the night key NK should be slowly operated several times. This will-open the .trunk line herein illustrated and The operation of the listeningr 8 will disconnect the repeating coil bridge from the trunk thereby permitting the central ofce supervisory relay (not shown) to release in synchronism with the operation of the night key. This will cause the supervisory lamp (not shown) :in the distant central olhce, to iiash.

When a calling subscribed Wishes to make an out-going call to a central oce, the trunk plug P is inserted in the station-jack J and the relays 58 and 59 Yare operated as previously described. Battery supply is furnished to the calling substation as previously described. P. B. X supervision as well as central office supervision provided in the manner already set forth.

Out-going calls to dial ollce When a subscriber at the P. B. X oiilce'makes a trunk call to a dial central office, the local trunk circuit operates in the manner already set forth. As soon as the P. B. X operator inserts the trunk plug into the jack ci the calling substation, if the dial equipment at the distant office is available, the subscriber will heal` a dial tone and should then proceed to dial the central office number desired. The relay 58 will be energized in the circuit already described which circuit includes the two sides of the telephone line in series. Each time that the Acalling subscribers line is interrupted at the substation thereof, by the operation of the dial, the relay 58 will vfol.- low these impulses and will open and close the repeating coil across the trunk line. The relay 59 which is slow releasing Will remain operated during the repeated energization and deenergization oi the relay 6B, to prevent the disconnect lamp Sl from lighting at this time. While the relay 68 is attracting and retracting its armature in response to the dial impulses, its contacts il?! and 33 are protected by the neon lamp L and the resistor R in series therewith, for the same purpose and with like advantage as described in connection with the selector circuit of Fig. 1.

It should here be pointed out that another con dition which .can have a serious eiect on the pulse ratio, is the high impedance discharge of the stepping relay in the selector or connector circuit of an automatic telephone system with which this repeater maybe used. This stepping relay is actuated by the contacts of the trunk repeater relay and should be so designed thatit faithfully reproduces the impulses set up bythe dial. `IIowever, in most types oif .dial systems,4 the stepping relay also serves as the battery supply relay to the calling party, and is designed for high impedance, so that voice frequencies will not return through the .central cnice storage battery, to cause cross talk. The present invention satisfies the .operating .requirements encountered in such connector circuits. Therefore. the relay rE8 will repeat the dial impulses substantiallyzum distorted. In response Ato each dial impulse, the relay @il will attract its armatures, .therebyclosing an impulse repeating circuit from the armature 82 of this relay, conductor 92, repeatingfcoil Winding B9, conductor 9.3, contacts .Sil oi' the dial key DTIAL, contacts .95 of thenlght key NIGHT, .trunk conductor 5t, leading to the distant'oice, through the winding of an impulse receiving relay (not shown) at that oiice, thence .through .the trunk conductor 5 I, ,contacts 9B' .of the night key, contacts Sil of the dial key, conductor 9.9 Winding of the repeating coilJ upper front contact and armature of relay 59', 'front contact '83 of relay 68 to the yarmature '82 4of this relay, at which point the'circuit is completed. -At the rst interruption ofthe subscribers line at the dial impulse springs (not shown), the relay 68 will release and at its armature 81 and back contact it will complete a circuit for energizing the slow releasing relay 88 which operates and is sufficiently slow in releasing that it will remain operated during the transmission oi the dial impulses. At the close of the series of impulses, relay 88 will release. When the relay 88 operates, it short-circuits both of the trunk windings 89 and 90 of the repeating coil to remove the irnpedance of all of the repeating coil windings, so that the dial impulses will not be distorted.

Supervision is provided for the P. B. X oper ator and for the central oiiice dial equipment, when the subscriber at the calling substation hangs up his receiver thereby causing the relays 68 and 59 to restore'.

Operator dialing If the P. B. X operator wishes to make a call from her switchboard to a dial central oflice, the listening key is operated as before and if an idle path in the dialing system at the distant dial central oflice is available, the operator will hear a dial tone. When the listening key is operated, the P. B. X trunk equipment will function in the manner already described.

In order for the P. B. X operator to transmit dial impulses it will be necessary for her to operate the dial key. The operation of this key opens the P. B. X trunk equipment and places the dial impulse contacts S8 directly across the trunk line. The dial key is equipped with make before break spring combinations on the tip and ring springs thereof so that the continuity from the repeating coil to the dial pulse contacts is maintained and at no time either in the operation or restoration of the dial key will the short or holding circuit be broken. This circuit arrangement is necessary to prevent preliminar pulses L which might result in wrong numbers.

When dialing has been completed, the dial key will be restored by the operator so that this operator may be connected to the trunk. At the completion of a conversation, the ringing key RK must be operated to release the locked-up relay 55 and restore the trunk equipment to normal. When the relay 55 is released, the holding bridge across the trunk line, namely, the repeating coil, is removed and the central cnice dial equipment is released. The make spring combination on the dial key which is parallel with a similar make spring combination on the listening key is required to operate the relay1 55 and light the hold lamp whenever a dial key is operated. The present trunk circuit is provided with a night service provision, theoperation of which need not be described in detail. It will be sufcient to understand that when it is desired to establish a night connection from a P. B. X substation to the P. B. X trunk, the battery cut-oit key (not shown) is operated and the trunk plug is inserted in the station jack. Whereupon the night key associated with the trunk is operated. lThe operation oi' the battery cut-oli key will prevent the supervisory lamps from lighting. When the night key is operated it closes the trunk line directly to the P. B. X station telephone line and opens the cord circuit as well as the trunk line from the P. E. X trunk equipment.

it should be mentioned that the relay is made slow to release so that the repeating coil bridge is left across the trunk line until the station short is established.

The relay 59 must be slow to release so that the 1,

vgizing the slow releasing relay IM.

10 red supervisory lamp 91 will not follow the dial impulses. It will be understood that when the P. B. X subscriber ilashes the P. B. X operator, the switch hook must be operated slowly in order for both relays to release and light the red supervisory lamp.

Connector In Fig. 5, the invention is illustrated as applied to a connector switch circuit. In the description of the connectorcircuit, it will be assumed that the subscribers substation A has initiated a call by removing his receiver from its desk stand. In response to this operation, the

calling subscribers line is extended in the welltor |83, lower continuity spring, back contact of` relay and lower winding of relay |00, to ground. As soon as the relay Hill1 is energized in this circuit, it vcloses an obvious circuit for ener- The connector is now in readiness to'receive the directive impulses'corresponding to the tens digit of the wanted subscribers number. Infresponse to each of these dial impulses, the relay |00 retracts and then attracts its armature. On the first retraction of the armature oi the relay |00,`

an operating circuit for ythe primary or vertical motor magnet |05 is completed from grounded battery, winding of vthis magnet, through the winding of the change-over relay H36 in series, conductor |31 through the contacts |08 now closed of the off normal switch, conductor |09, lower front contact and armature of the slow releasing relay |'4, back contact and armature of relay |530, to ground; 'In theconnector circuits the back contact and armature contact of the relay |D have the glow lamp L and the resistor R connected in shunt thereof. The primary motor magnet |05 on being energized in circuitabove described, moves the brushes Ill), and

||2 of the connector switch one step in theirprimary direction. As soon as this step is completed, the ori normal switch operates and reverses the position of its contact springs from ...A the position-illustrated. In response to the next 55 leasing change-over relay in series therewith, 60

front `contact and armature oi this relay, conductor H3, on normal switch contacts H4, now closed, conductor |09, iront contact and armature of relay m4, back contact and armature oi the relay |00. In response to each of the succeeding tens impulses, the primary lmagnet |5 will advance the connector switch brushes one step. The slow releasing relay |84 remains operated during each response of the relay |00 to the dial impulses and, of course, remains energized at the conclusion of these impulses.

However, at the end of the tens series oi impulses the change-over relay |36, deenergizes, and at its front contact and armature interrupts the operating circuit of the primary magnet |05.

Also when the change-over relay |06 deenergizes.

i 1 it. completes a brealseocint operating circuit .for the. secondary orrctary motor magnet liti, from grounded battery, winding of this magnet, armature and back Contact of the relay H6, armature and back Contact of the relay IIT, back Contact and armature of the change-over relay |05, o ff normal contacts H4, conductor |09, front contact and armature of the relay |04, back Contact and armature of the relay |90 tov ground, when relay Inl) retracts its armature in response to the rst impulse of the series corresponding to the units digit. The slow releasing relay lla is energized in multiple with the initial operating circuit of magnet H5. When relay ||8 is thus energized, it closes a new operating circuit for magnet I5 and a locking circuit for itself through its lower armature and front contact. This locke ing circuit is independent of the lower armature and back contact of relay |I'| which might otherwise operate and interrupt the stepping circuit for magnet ||5 when the test brush HB of the connector passes over busy lines. In response to each of the ren'lainingv impulses cor-A responding to the units digit of the wanted subscribers number, the impulse relay will retract its armature and subsequently attract this aro mature thereby completing the circuit just described for the secondary motor magnet H5. ln response to each operation of the motor magnet H5, the connector switch brushes H0, and H2 will be advanced one step in their'secondary movement to select the wanted line in the ses. lected group.

At the conclusion of the units series of iinpulses but before the slow releasing relay ||8 releases, the test of the wanted line is effected. It this line is idle, the slow releasing cut-.through relay i6, will operate in series with cut-on ree lay (not shown) of this line, in a circuit from grounded battery, winding or the mentioned cut.

ofiiv relay, test brush IIB, upper armature and back contact of relay ||`8, lower winding of re. lay IIB, back contact-and armature of relay H1, conductor |20, armature and front contact of relay |04 to ground. Relay IIE on operation, locks itself operated from grounded battery, its upper winding, its inner front contact and arT matura-conductor I2|', inner front contact and armature ofv relay mit to ground.

Ringing current is applied to the called line through the trip relayy |22 and when the called party answers byremov-ing his receiver from its switch hook, relay |22 operates. When relay |22 operates, it locks itself operated through its lower winding, front contact and armature over conductor |2| to ground at; the armature and front contact of relay IM.

When the Called. iiarty answers relay I M is energized over the two sidesk ci the calledr line in, series through the front contacts and arma-` tures relays IIB and |22. Relay I|'!| energizes andY reverses the battery feed through the windings of relay iBfI to the respective sides of the callingl connection. Battery for' the called end ofy the. connection is supplied through the windings of relay IIJI.

if' the called line is busy, test relayy i IT, will be operated in a circuit from grounded battery, back contact and middle armature ofr relay I |3, upper front contact and armature of relay IES, test brush I I0, test terminal of the called and thence through a test such as ||0 ofr a connector that has. seized thev Wanted line and thereby made it busy, to ground at the lower middle armature.

'i2 and iront Contact of a relay similar io H6 at the mst-mentionedconnector,-

At the. termination cf. the connection relay .|04 will release, to energize the release magnet |24 which restores the connector switch the wellknown manner.

' In ,the diagrammatic Showing of Fie.. 6, the invention is illustrated as applied to the operate ing circuits of a counting relay chain. In this arrangement it is assumed that the calling sub.- scribers substation at A. has been connected to the counting relay chain unit in any well-known. manner. As soon as this connection is eected the impulse relay |35 is energized from grounded battery, upper Winding 0f this relay through. the mentioned link connection to the calling stilistation and thence over the lower side 0f the 6011,, nection, lower winding of the relay ISB to ground;4 The relay |33 is energized in this circuit and at its upper armature and front contact, it completes an obvious circuit for the slow releasing relay |3| which controls the release of the counts ing relay chain unit. Also as soon as the relay |38 is operated, a circuit is completed for the relay |32 which primes the counting relay chain for operation, rThe relay |32 is operated from grounded battery, winding of this relay through the lower back contacts and armatures of the counting relays CI through C3 and C0, relays C2 through C8 being omitted for simplicity of diss, closure, and thence over the stick-up conductor |33, which is completed to ground at the armature and frontcontact of relay IBI. With the relay |32 thus operated, a circuit is prepared forthe No. 1 counting relay, from grounded battery, winding of this relay, upper front contact and armature of the relay E32, conductor |34, front contact and armature of relay |3t, back contact and armature of the impulse relay |39, when this relay releases in response to the first impulse of the series. Likewise, the change-over relay- |35 is energized from grounded battery and thence over the conductor |34, front contact and armature of the slow releasing relay ISI, back contact and armature of the relay |33 in response to this last-mentioned impulse. The No. 1 counting relay when energized is locked operated from grounded battery, its upper armature and front contact, conductor l3, back contact and armature 0f the relay |38, lower armature and front contact of relay |3I, to ground. When the irnpulse relay |39 again operates the counting re lay Ci is then locked up, from grounded battery through its winding, thence through its lower front contact and armature through the bach contacts and armatures of the remainder of the counting relays of the chain, holding conductor |33 to ground. Also, when the No. l counting relay is operated, as just described, an operating circuit is prepared from the No. 2 counting relay (not shown) from grounded battery, uppermost front contact and armature of the No. 1 counting relay, back Contact and armature of the relay |32. now released, conductor ISG, front Contact and armature of relay |3l, back contact and armature of relay E3B, to ground. Y

The impulsing system of Fig. 6, likewise, has incorporated therein the discharge device L and the series resistor R of the present invention which are connected across the uppermost contact and armature of relay |30, as well as the device Land resistor R which are connected to the holding conductor |33 as shown. These devices and resistors function in the same manner and for the same purposes as already set forth.

While the invention. has been disclosed in connection with telephone systems, it is not so limited, but is applicable to various electrical systems and devices wherein rapidly interrupted contacts are employed.

What I claim is:

1. In an automatic telephone system, an impulse repeating relay, an operating circuit for said relay, a dial impulse sender having contacts in said circuit for interrupting and closing the same to generate impulses in accordance with a given impulse ratio, stepping means, a stepping circuit for said stepping means including contacts of said impulse relay, a resistor and an ionizable gas discharge device connected in series across said contacts of the impulse relay, means in said discharge device for providing some emission therein at all times during normal conditions of use whereby the impulses repeated by said impulse relay are not distorted but are stabilized in accordance with the given impulse ratio.

2. In an automatic telephone system, a plurality of telephone lines each provided with a dial impulse sender for generating impulses in accordance with a given impulse ratio, means including an automatic switch for interconnecting said telephone lines, means including a primary motor magnet and a secondary motor magnet op erative in succession for advancing said switch to extend a calling telephone line to a called telephone line, an impulse repeating relay associated with said switch, said relay having contacts operated thereby in response to impulses transmitted by the dial sender of the calling line in accordance with a given impulse ratio, a circuit for said primary motor magnet including in series therewith a slow releasing changeover relay and the contacts of said impulse relay, a circuit for said secondary motor magnet extending through normally closed contacts of said changeover relay and the mentioned contacts of said impulse relay, an arc discharge tube as well as a limiting resistor connected in shunt oi the contacts of said impulse relay, to constitute the only shunt across said contacts, and means in said 'discharge tube providing some emission therein at all times during normal conditions of use whereby impulses repeated by said relay to the respective magnets are not materially distorted but remain substantially stabilized.

3. In an electrical impulsing system, a set of rhythmically opened and closed contacts, a glow lamp comprising spaced electrodes in an atmosphere of rare gas, such as neon, enclosed in a sealed envelope, said glow lamp having the characteristic of ionizing on the application to its respective electrodes of a difference of potential of the order of ninety volts across said electrodes and of maintaining its ionization at a sustaining diierence of potential of eighty volts, a resistor of the order of four thousand ohms connected in series with said glow lamp and both connected in shunt of said contacts, and means including at least one of said electrodes for providing some emission in said lamp at all times while the lamp is thus connected.

4. In an electrical impulsing system, a direct current source having a voltage in the range below fifty-one volts, a set of normally closed contacts, means for rhythmically opening and closing said contacts, a relatively high impedance electro-magnetic selecting means, connectible in series with Said contacts and with said source ci direct current, a glow lamp comprising spaced electrodes in an atmosphere of rare gas enclosed in a sealed envelope, said glow lamp having the characteristic of ionizing on the appli-cation to its respective electrodes of a dilierence of potential or the order of ninety volts and of maintaining its ionization at a sustaining 4diierence of potential of eighty volts, a resistor of the order of four thousand ohms connected in with said glow lamp and both connected in shunt of said contacts to constitute the only shunt across said contacts, and means including at least one of said electrodes for providing some emission in said lamp at all times while the lamp is thus connected.

5. In an automatic telephone system, an impulse relay having at least a set of normally open contacts and a set of normally closed contacts, a source of impulses having a predetermined impulse ratio, means for applying said impulses to said impulse relay for operating said sets of contacts in accordance with said ratio, a slow releasing relay having at least a set of normally open control contacts, an operating circuit for said slow releasing relay completed at rst mentioned open contacts, electromagnetically oprated selecting means, a circuit for said selecting means including in series relation, said set of normally open control contacts and said set of normally closed contacts, an ionizable gas discharge device and a resistor in series there with connected in shunt oi both of said last-- mentioned sets of contacts, and means in said discharge device normally providing some emission therein at all times during use.

6. In an electrical impulsing system, a set of normally closed contacts, means for rhythmically opening and closing said contacts, an arc discharge device in series with a resistor connected in shunt of said contacts to constitute the only shunt across them, and means in said discharge device normally providing some emission therein at all times whereby substantially no electrostatic charge is retained in said device during use.

JAMES R. DEWAR.

REFERENCES CITED The following references are of record in the le of this patent:

UNITED STATES PATENTS Number Name Date 1,729,858 Ruggles Oct. 1, 1929 1,966,077 Nyrnan July l0, 1934 2,179,826 May Nov. 14, 1939 2,315,378 Powell Mar. 30, 1943 2,322,650 Matousek June 22, 1943 2,434,065 Courtney Jan. 6, 1948 FOREIGN PATENTS Number Country Date 392,898 Great Britain Aug. 21, 1931 588,204 Germany Nov. 14, 1933 OTHER REFERENCES Electrical Contacts, by G. Windred, MacMillan & Co., Ltd., St. Martins St., London, 1940, pp. 24o-268. 

